DISTRIBUTION PATTERNS OF OXIDATIVE ENZYMES IN EXPERIMENTALLY INDUCED TUMORS, REGENERATION AND INFLAMMATION OF MOUSE SKIN

Abstract

Enzyme histochemical studies of normal and burned mouse skin as well as those treated with methylcholanthrene or 2,4-dinitro-1-chlorobenzene revealed that the irritant (or stimulus) carcinogenic or noncarcinogenic, initially results in a more distinct polarization² of the localization of oxidative enzymes including glucose 6-phosphate dehydrogenase (predominant in the upper layers of the hypertrophic epidermis) and DPN-dependent dehydrogenases, succinic dehydrogenase and cytochrome oxidase in the lower layers. Subsequently, only the carcinogen disrupted the polarization pattern. Methylcholanthrene-induced squamous cell carcinomas were classified from a histochemical standpoint according to the following three types: (1) those well differentiated and having a distinctly polarized pattern of oxidative enzymes; (2) those showing disruption of the polarization pattern and marked activity of oxidative enzymes; and (3) those that were undifferentiated and characterized by absence of a polarized pattern and weak activity of oxidative enzymes. Type 1 showed an enzyme distribution pattern resembling that of the inflammatory hypertrophic epidermis; type 2 was similar in enzymatic pattern to the advancing proximal portion of the regenerating epidermis; and type 3 was similar enzyme-histochemically to the undifferentiated epithelium of the early embryo skin. Thus, a great variation in the distribution pattern of enzyme activities appears during the carcinogenesis process.